Method and apparatus for destroying insect life in flour and the like in bulk



-Mar;ch 2, 1943. F. 5. SMITH 2,312,368 METHOD AND APPARATUS FOR DESTROYING INSECT LIFE IN FLOUR AND THE LIKE IN BULK Filed March 16, 1939 8 Sheets-Sheet l INVENTOR Fran/(Lin 5. Sm'L i/I /4 SYN/[MM ATTORNEY SMITH a sheets-sheet 2 March 2, 1943. s

' METHOD AND APPARATUS FOR DESTROYING INSECT LIFE IN FLOUR AND THE LIKE IN BULK Filed March; 16-, 1959 March 2, 1943.

F. 5. SMITH METHOD AND APPARATUS FOR DESTROYING INSECT LIFE IN FLOUR AND THE LIKE IN BULK Filed March 16, 1939 8 Sheets-Sheet 3' Franklin 5. Smith F. 5. SMITH 2,312,358

DYING INSECT 8 Sheets-Sheet 4 March 2, 1943.

METHOD AND APPARATUS FOR DESTR LIFE IN FLOUR AND THE LIKE IN BULK Filed March 16, 1939 a 0 v 5 8 A$ 8 9 2,312,368 INSECT 8 Sheets-Sheet 5 March 2, 1943. 5 sMlTH METHOD AND APPARATUS FOR DESTROYING LIFE IN FLOUR AND THE LIKE IN BULK Filed March 16, 1939 lNVENTOR Fran/(Mn 5. Smith WM W ATTORNEY F. 5. SMITH 2,312,368 PPARATUS FOR DESTROYING INSECT FLOUR AND THE LIKE IN BULK Filed March 16, 1959 March 2, 1943.

METHOD AND A LIFE IN 8Sheets-Sheet 6 W 0 a 0/ 4 W M w w u/ /v 7 HM W 2 2 Z0 6 W 2 w w x a, v1 0 Z l 4 3 3 a m 2 W Z l m 2 5 Z Z.

In R W m W5 5 Vn WU Ln n. m Fm VI 5 ATTORNEY March 2, 1943. F. 5. SMITH ETHOD AND APPARATUS FOR DESTROYING INSECT LIFE IN FLOUR AND THE LIKE IN BULK Filed March 16, 1939 8 Sheets-Sheet 8 INVENTOR Franklin \ifimllill ATTORNEY Patented Mar. 2, 1943 UNITED TQES FFioa METHOD AND APPARATUS FOR DESTROY- ING INSECT LIFE IN FLOURAND THE LIKE INBULK This invention relates to a method and apparatus for destroying insect life in food products,

particularly milled products in bulk, such as flour.

One of the objects of this invention is to provide a practical, dependable and efllcient method and apparatus for treating food products of the above-mentioned nature to achieve the destruction of insect infestation therein, usually in the form of eggs, larve, pupae, or adults. Another object is to provide a method and apparatus of the above-mentioned character whereby such products may be so treated in bulk and more particularly in the course of theirmovement along a continuous stream or path of flow and thus also to make it possible to interpose my method or apparatus at any suitable or appropriate point in the otherwise usual or normal production or handling in mills of such products.

Another object is to provide a safe and efllcient method and apparatus for electrically destroying insect life in flour and to carry out that object in a manner that is free from the danger of socalled dust explosions. providea practical, simple and dependable apparatus for achieving a continuous flow or movement of flour or like products, to efiect electrically the destruction of insect life therein, and at the same time to so control the flow or movement of the product that such electrical action is achieved without giving rise to the possibility of flour dust explosion. Another object is to provide an apparatus of the above-mentioned character in which the destruction electrically of in'- sect life may be achieved by disruptive discharge or spark-over and to achieve simple and depend- Another object is to able control or determination of the rate of flow oi the flour product through the discharge zone and of the mass or quantity of flour product present at any moment in the discharge zone. Another object is to provide in apparatus of the above-mentioned character simple and effective means for dependably so correlating the energy of electrical discharge and the nature and character of movement of the flour or flour products that dust explosion cannot take place.

Another object is to provide an apparatus and rrethod for treating comminuted food products like flour, in bulk, and to provide simple and dependable control of the product so as to negative or minimize the creation of a dust-like atmosphere laden with particles of the food product being treated, and thus to avoid giving rise to explosive dust atmosphere. Another object is to provide a simple and dependable method and ap- 32 Claims. (Cl. 21-102) paratus for effecting continuous or steady flow of I comminuted food products like flour into or through the treatment zone. Another object is to provide a dependable method and apparatus for efiecting suitable flow at appropriate density of the comminuted product into or through the treatment zone. V

Another object is to provide a safe and compact flour-treating apparatus, capable of reliable and e'fiicient action, and well adapted to meet the varying requirements and conditions of practical use. Another object is to provide an. apparatus of the above mentioned character that will be capable of facility of'assembly or replacement of its various parts. Another object is to provide an apparatus for electrically treating comminuted .food products like flour that will be dependably free from danger of dust explosions and in which the fiow or movement of the finely divided product is controlled with such dependability that electrical apparatus of high voltage and also electrical discharge devices may be safely and dependably associated with it. Other ob- Jects will be in part obvious or in part pointed out hereinafter.

The invention accordingly consists in the features of construction, combinations of elements,

arrangements of parts and in the several steps and relation and order of each of the same to one or more of the others, all as will'be illustratively described herein, and the scope of the application of which will be indicated in the following claims.

In the accompanying drawings in which are shown several of the va ious possible embodi-' ments of the mechanical and electrical features of my invention,

Figure 1 is a front elevation on a small scale of one form of apparatus;

Figure 2 is a plan view as seen from above in Figure 1, certain parts being broken away and certain other parts being removed in order to show certain features of the construction more clearly;

Figure 3 is a central vertical sectional view, I

in section, of a connector device for facilitating Figure 12 is a horizontal sectional view, as seen along the line 52-42 of Figure 11;'

Figures 13 and 14 are perspective views on a larger scale of companion parts of an insulating structure for housing a winding and for effecting assembly of winding and certain core construction and pole pieces of generator units embodied in the construction of Figures 1.1 and 12;

Figure 15 is a perspective view on a larger scale of a lamination of a core leg of the generator units;

Figure 16 is a perspective view on an enlarged scale of a pole piece for a permanent magnet element of the generator units;

Figure 17 is a perspective view on a larger scale of a spacer of insulating material used in the generator units;

Figure i8-is a plan view of the apparatus of Figure 10 with certain of the parts being broken away;

Figures 19 and 20 are diagrammatic perspective views showing respectively two ways of assembling or interrelating certain elements of the above-mentioned generator units;

Figure 21 is a front elevation with the left half in central vertical section, of another form of apparatus;

Figure 22 is a horizontal sectional view as seen along the line 2222 of Figure 21;

Figure 23 is a perspective view of a mounting part employed in the construction shown in Figures 21 and 22;

Figure 24 is a'perspective view of a mounting member companion to that shown in Figure 23.

Similar reference characters refer to similar parts throughout the several views of the drawings.

Referring now to the drawings and more particularly to Figures 1, 2 and 3, I preferably provide a suitable base or standard, illustratively in the form of several pedestals or legs 25, illustratively four in number and preferably grouped equidistantly about a central vertical axis, adapted to rest upon a floor or like support and to be secured to the latter in any suitable way if desired; the legs or standards 25 support and have secured thereto an annular base portion 26 of a casing or housing later to be described and also an annular flange 2'! that extends about and is preferably formed integral with a tapered or frusto-conical member 28 whose vertical axis preferably forms the central verticalwaxis of the apparatus and with respect to which I preferably aaiaees the outer peripheral portion of the part 26 has secured to it as by welding an upwardly'extended cylindrical casing part 33 closed over at its upper end by a cover plate 3! (Figures 2 and 3), the cover plate 3!, certain details of which are later described, having at its center a round opening with which is associated, in a manner later described a suitable means forming an entering opening or passageway through which the comminuted food product like flour enters the apparatus within the casing structure. This entry opening or passageway, indicated in Figures 2 and 3 at 32, may be connected in any suitable way, as by a conduit (not shown) to receive the product which, after treatment in the manner later described, is discharged through the exit opening 33' (Figure 3) at the bottom end of the frusto-conical member 28; the opening33 is preferaoly constructed as indicated in Figure 3 to permit securing it to a conduit, or the like, to pass the product on. It will be noted that preferably entry opening 32 and exit opening 33 are coaxial with the central vertical axis of the apparatus as a whole, and thus the completely encased. apparatus may be easily and quickly connected into an existing arrangement of machines or mechanisms or the like of amill for the preparation and handling of such food products.

lower end of an angle-cross-sectioned ring 38,

being secured in place as by screws 39 and being provided with a suitable number of inwardly and radially extending arms 40 (Figures 2 and 3), arms 40 terminating in a ring member 4| whose upper end, as seen in Figure 3, is rabbetted as at 32 and 43. It is with the outer of these two rabbets, namely rabbet 42, that the above-mentioned centrally aperturedf cover plate 31 interfits, the outermost and peripheral portion of the'cover plate 3| (see Figure 3) being suitable strengthened or reinforced by an annular downwardly extending rib 3| which rests upon an inwardly extending flange 3|] of the cylindrical casingportion 30, to which flange 30* the annular cover plate 3| may be secured as by cap screws 44.

The above-mentioned ring member 4| (Figure 3) is by the arms 40 and the ring 38 and rabbet 36 positioned and held coaxial with the central vertical axis of the apparatus and hence and preferably is made to relate certain other parts coaxially with this vertical axis. Thus, in the rabbet 43 (Figure 3) of ring member M is seated the flange of a member 45 which, like the frustorelate other parts of the apparatus, as later described.

As better shown in Figure 3, the upper ends of the legs 25 may be provided with a flange 25* against which the overlapped adjacent and apertured ends of the annular members 25 and 21 are supported and to which they may be clamped or secured as by cap screws 29.

The parts 26 and 21 thus form a closed annular bottom for the casing structure, with the lower portion of the frustoeconical'member 28 projectmg centrally and downwardly therefrom, while conical member 28, is preferably made to serve both as an auxiliary support and a guidew'ay or passageway. Thus, member 45, preferably in the form of a casting, may be in general cylindrical in shape to extend downwardly into the f'rustomember 28 to an-appropriate extent and "also coaxially therewith, its upper end being conveniently tapered outwardly to form the abovementioned entry opening or passageway 32 for the product to be treated. Member 45 may thus be assembled to the apparatus from above, being let down into and through the ring support ll to which it may be secured as byscrews l6.

Bridging across and in effect bifurcating the upper end of the passageway through the member 45 and preferably formed integrally therewith is a cross-rib 48 (Figures 3 and 2) with a hub-like enlargement 49 at its center to provide adequate material and strength after being bored out as at 50, again along the above-mentioned central vertical axis, to receive therein and to position coaxially with that vertical axis a downwardly extending relatively rigid and strong tube-like support Tube-like support 5| may be rigidly secured in the bore 50 in any suitable way, preferably as follows:--Thus, the upper end portion of tubular support 5| may be of reduced diameter to be snugly received in the bore 50 and to provide a shoulder 53 (Figure 3) against which rests the inner race of a combined radial and thrust antifriction bearing 54, there being interposed between that inner race and the counterbored part 49 of the hub portion 49 a sleeve 55; the extreme upper end of the tubular support 5| is threaded to receive a nut 56 which, when tightened up, clamps the hub portion 49, the sleeve or collar 55, and the inner race of the bearing 54 between itself and the shoulder 53, thus rigidly securing the tubular support 5| in depending relation to and coaxially with the frusto-conical frame member 28 and related parts. Key 52 positions and retains support 5| in correct circumferential relation to hub 49.

The uppermost end of the tubular support 5| negligible resistance to the downward flow of the material. I

Spaced downwardly from the bearing 54 (Figure 3) the tube-like support 5| is shouldered as at 58 to receive thereon and against the shoulder the inner race of a combined radial and thrust anti-friction bearing 59, the outer race of which is received in a suitable seat formed as at 60 at the lower end of a rotatable sleeve shaft member 6| that extends upwardly and about the tubular support 5| and well into the counterbore 49 of the hub portion 49. At its upper end the sleeve shaft 6| is shouldered as at 62 to receive thereagainst the outer race of the bearing 54 which is secured or clamped against the shoulder by a collar 63 pressed into the upper threaded end of the sleeve shaft 6|. The sleeve shaft 6| thus extends downwardly. along the axis of the member 45, and, with the cylindrical wall ofthe member 45, the external cylindrical surface of the sleeve shaft 6| forms an annular downward passageway extension 64 of the above-mentioned entry opening or passageway 32. But sleeve shaft 6| is also dependably supported for rotation and by the above-described construction 1 shaft 5| with other parts related to it as later described may, as a unit with the tubular support 5|, be assembled to the hub portion 49 of the supporting ring 4|.

As above noted, the member 45 is preferably also made to serve to take part in supporting certain other parts; thus, it is provided with a horizontal annular flange 65 (Figures 3 and 9) suitably shaped to form an annular seat for a frusto conical member 66 made of any suitable solid dielectric material like Bakelite .and secured in position as by screws 68. And, asis better shown in Figure 3, the upper end of the member 66 is flanged or extended horizontally, as at 66, being rabbeted, as shown, to interfit with gasket 61 on the rabbet 31 of the flange portion 34 .of the frusto-conical member 28. The solid dielectric member 66 may thus be given a strong and dependable mechanical support while its external surfaces, as viewed in Figure 3 comprise a frustoconical surface substantially paralleling the internal surface at the upper end of the frustoconical member 28, suitable curvatures or configurations being provided to merge the outer surface of member 66 into the curved surface of member 28.

The lateral face of flange 65 is preferably shaped to form a downward continuation of the frusto-conical surface of member 66, and that in turn is extended downwardly and inwardly to merge into or join the lower open end of the passageway 64 in the member 45; for this latter purpose I may provide a frusto-conical part 10, which may be metallic, shaping it at its lower end so that it snugly fits over the lower end of the member 45 and shaping it at its upper end to rest against the under face of the flange 65 to which it may be secured as by screws II.

Projecting outwardly from the insulating frusto-conical member 66 and extending and preferably uniformly distributed'throughout a suitable band-like portion of member 66 are electrodes 12 which, as shown in Figure 3, are, by

Way of illustration, arranged in three circular later described in detail though it might at this point be noted that they are preferably so energized that in coaction with a companion electrode structure about to be described they form an annular or ring-like treatment zone in which preferably disruptive discharge takes place; with the comminuted food product, hereinafter for convenience simply called flour, entering the apparatus through the entry opening 32 and passing downwardly in the annular passage '64 (Figure 3) to emerge from the lower end of the latter, the flour is now to be brought at a suitable rate of flow or movement and at an appropriate density into and through this annular treatment zone to be subjected to the discharge emanating from the electrodes 12. For this purpose, and in the light of the peculiar physical characteristics of flour, such as its finely pulverized character, its variable degree of compacting under force or pressure, its tendency to form dust-like suspensions in the air, and the like, I prefer to relate the annular passageway 64, thence upwardly and outwardly past the electrodes 12. The, ends or discharge surfaces of the latter are preferably alined to be equidistant from the juxtaposed portion of the inner surface 14 of the rotatable member 13, thus to insure substantial identity of gap as better appears in Figure 3, to interfit with a suitable rabbet ":75 formed in the upper face of a disk-like flange or carrier l6 preferably formed integrally with the sleeve shaft 6|, just below the lower mouth of the part 45. Member '53 may thus be easily assembled to the sleeve shaft GI and secured to the flange 16 thereof as by screws it; it thus partakes of the rotation of the sleeve shaft 6i and preferably it is dynamically balanced so that its rotation even at high speed is substantially vibrationless.

When driven at a speed suitable to the curvature or inclination of its inner surface 14 and to the radii from the axis of rotation, the member i3 effects a steady and continuous upward and outward flow of the flour along its surface 14 into and through the treatment zone, in a preferred manner described in greater detail later, whence it tangentially discharges into the interior. of the frusto-conical member 28 down which it slides to be discharged through the discharge opening 33. Accordingly, by suitably correlating the factors of speed of rotation of the part I3, the dimensions and shaping of the interior surface of the latter, and the particular characteristics of the comminuted food product to be treated, a desired or suitable rate of flow of product, density or degree of compacting of the product in the treatment zone, or thickness of the layer of the product in the treatment zone may be achieved.

For example, for the sterilization of flour, satisfactory results are achieved where the speed of revolution of the member "i3 is 1150 R. P. M., with the dimensions and shape of the surface 74 of member 713 substantially as follows: minimum internal diameter approximately 9", maximum internal diameter 20", height 12.5"; preferably the radius of the surface it in passing from the plane of minimum diameter to the plane of maximum diameter varies non-linearly and hence the surface 7 when viewed as in'the section of Figure 3, partakes of some curvature. Illustratively, the curvature is or may approximate a portion of a hyperbola whose asymtotes .subtend an angle of about 36. More particularly, in the just stated illustrative example, only a portion of the hyperbola is employed, and such a portion that the angle subtended by tangents at the-points X, X

in Figure 3 (the place of minimum inside diameter) is about 60, and the angle subtended by tangents at the points Y, Y (where the diameter is maximum) is about 38. With such an illustrative structure, the member l3 passes flour upwardly into and through the treatment zone at the rate of about 400 pounds per minute, maintaming a steady upward and outward progression of the flour along the surface 74, moving it through the annular treatment zone about the electrodes 12 in a substantially steady or continuous layer of an average thickness preferably not exceeding'about half" the spark-gap length, the latter being about 0.5".

' It is desirable to maintain substantial constancy of speed of rotation of the-combined transport and electrode members 13, for it is possible that too great departures from the speed that is optimum for the other factors, such as rate and range of change of radius of the surface 14, might detrimentally affect the achievement of all ofthe desirable advantages and results of the.meth od and apparatus or impairthe efiiciency or effectiveness of other desirable functions of the apparatus. Accordingly,. I prefer to associate aeiases characteristic of substantial constancy of speed of rotation, as attained in commercial practice.

Preferably, this takes the form of an electric motor, preferably of the alternating current type, such as, for example, an induction motor, the speed of drive of which, the .power supply and load being substantially constant, would likewise be substantially constant. Conveniently, the tubular support 5| has an enlarged downward extension provided with a shoulder 8| against which are clamped, as by a clamping ring 82, the laminations of afield or stator structure suitably shaped or conformed to have related to it energizing windings 83.

The rotating element or rotor of the motor may comprise suitably shaped laminations 64 which are clamped by a clamping ring 85 .held by screws against a shoulder 86 formed internally in. a dome-like housing or casing 88 which takes over and encloses the downward extension. of the tubular support 5| with its stator core and winding, being secured as by screws 88 against the under face of the disk-like flange or carrier 16 of the sleeve shaft 6!, being suitably centered or alined therewith in any suitable way as, for example, by interfitting with a rabbet, as shown in Figure 3, on the under face of the flange l6.

Electrical connection to the windings 83 is preferably achieved by way of conductors 90 which extend into and through the passageway 56 and through a hole in the tubular support 5| which alines with a passageway 43 formed in the cross-rib 48 and through a connecting passage in the ring member 4| (Figures 2 and 3); to the latter a suitable conduit or the like, indicated at 9!, may be connected to lead the conductors to the source of energy supply.

Accordingly, energization of the windings 83 sets the rotor 84 into rotation, driving the sleeve shaft GI and the bowl-like member .13 directly through the motor housing or casing 88 connected thereto as above described. The motor may be designed and constructed to give a speed of rotation of 1150 R. P; M., in the above-described illustrative example, and may be of such a type or of such characteristics as to achieve and maintain substantial constancy of speed.

With substantial constancy of speed of drive of the member 13, the action of the latter upon the flour may be maintained substantially uniform and invariable. Flour is fed, by suitable conventional means not shown, to entry opening 32 of member 45 in such direction that the flour stream is bifurcated by cross-rib 48. The flour,

having air entrained with it, then descends by gravity in the annular passageway 64 of member 45 in a stream of somewhat uniform distribution of cross-section. Upon contacting the'annular bottom of the rotating member 13 the flour partakes of the rotory motion of member 13 and is distributed rapidly and uniformly about the axis of rotation of member 13. Due to the centrifugal force exerted'by the moving flour, the flour moves in an outward direction and hence against the lowermost portion of the upwardly and outwardly inclined inner surface 14 of member 13, for ex- I ample, against portion a: in Figure 3.

Due to the configuration of the surface 14 of member I3 which effects a control of the varia- I tion in centripetal force acting upon the flour, and due to the centrifugal force exerted by the flour and its entrained air, the flour and air move outwardly and upwardly in expanding curvilinear paths about the axis of member 13.

Just prior to the flour and air entering the 2,312,368 treatment zone a suflicient centrifugal separation of flour and air has been effected, so that an outer annular layer of flour substantially free of air and an inner annular layer of air substantially free of flour in suspension. pass through the treatment zone.

Thus, a, steady upward fiow of flour along the surface 14 ofmember I3 may be effected, and a dependable passage of the flour with its contained insect infestation into and through the treatment zone brought about, and in the preferred form the actual path of movement of any particle of flour,

with respect to the vertical central axis of member 13, is a composite or a resultant of a helix and a spiral. In the illustrative form, it is possible to achieve an effective flow of flour at the rate of about 400 pounds per minute with an average thickness of flour layer as it passes the electrodes 12 in the annular treatment zone about a quarter of an inch, where the lengthof the spark gap from the tip of any one electrode 12 to the surface M of the common electrode member 13 is about one-half inch. The rate of supply or feed of flour to the apparatus may, of course, be cut down if desired or according to operating requirements, and in such case the rate of flow of flour is correspondingly less and the average thickness of flour layer in the treatment zone correspondingly diminished. First, I make certain that no flour particles are suspended in dust-like formation in any air space between the inside surface of the layer of flour and the external frusto-conical surfaces of the members 10 and 66 (Figure 3). The above-described centrifugal action by the flour particles precludes the production of any dust-like atmosphere in any such air space, and thus the sparkover or electrical discharge from the electrodes 12 to the companion electrode member 13 may freely take place without danger ofv dust explosion. Also, the above described centrifugal separation of entrained air from the flour compacts the flour particles in the upwardly moving layer,

preventing particles from flying off of the surface of the layer to create a dust atmosphere and also insuring a steady progression of the particles into and through thetreatment zone. In such compacted form, the flour is subjected to the electrical discharge, its occupied volume being about halved or its apparent density about doubled. Thus also the spark discharge cannot dislodge flour particles into the inner layer of air to form an explosive mixture.

' When the fiourreaches the upper edge of member 13, the centripetal and centrifugal forces collapse and it discharges tangentially. Preferably, it discharges through a plurality of slot-like apertures l3 distributed peripherally about the upper edge face of the member 13, as is better shown in Figure 10; these apertures are preferably formed between vane-like members I3 which may be formed integrally with the member 13, members 13 being surmounted by an annular flange 11 secured as by screws or rivets l9. 1

As is' better shown in Figure 3, member" has its upper face parallel and closely spaced to the under face of the horizontal portion 63* of the insulating member 66 and preferably acts also as g centrifugal fan to prevent ingress of air and our. j

The vanes 13 preferably also act as impellers, their leading vertical faces having suitable inclination, as indicated in Figure 10, assuming clockwise rotation of th member 73; they thus coact with the member 13' in tangentially ex.-

pelling air from the treatment zone and also the flour as it reaches the upper edge of member 13. These actions may also help prevent such turbulence in the treatment zone as might stir up flour particles and bring them" into suspension in the air. Also, such an outward flow of air from the treatment zone may act-as a dependable barrier to prevent any air with flour suspended in it from entering the treatment zone from the discharge space externally of the member 13. Illustratively, as earlier noted, the electrodes 12 are preferably numerous and preferably uniformly distributed, as above described, for example, in three rings or rows of seventy-two electrodes each. If the electrical energy impressed across the spark gaps is of suitable frequency, for example, cycles per second, a disruptive discharge or spark-over takes place at each electrode 12 for each half wave of the alternating potential applied. The band-like or annular treatment zone, when the electrodes are ener-,

charges take'place in rapid succession or repetition; for convenience and lower cost of manufacture, the electrodes 12 may be and preferably are uniformly distributed throughout this zone. Thus, in the illustration, .they are arranged in three circular rows, the lower row being preferablyspaced vertically from the central row slightly more than the upper row is spaced from the central row, as seen in Figure 3, and the electrodes in each row being equally spaced as will later be set forth, this arrangement resulting substantially in equidistant spacing of all electrodes.

But with respect to such preferred uniform distribution of the discharge electrodes 12, the path of movement of any portion or particle of the flour or its insect infestation that is to be treated, is such that it cannot escape being presented in juxtaposition to more than one of the electrodes 12 since the path of movement of any such portion or particle, due to the rotation of the member I3 and due to the upward movement of the flour, is a composite of these two effects and hence is, as earlier noted, a composite of a helix and a spiral relative to the axis of the electrode 72.

Thus, it becomes impossible for an insect in any stage of its life to escape destruction, if it is contained in the flour thus passed through the treatment zone. The insect contamination need not be directly juxtaposed to an electrode 12, since the discharge emanating from the elec,-

trode in effect seeks out the contamination be-' cause the relatively higher permittivity of the insect, in whatever its form, is high as compared to the adjacent media, and because the spark gap length substantially exceeds the thickness from corona; this is preferable in order to avoid substantial ozone production, in such cases where subjection of the product to ozone is not desired or is objectionable. A suitable and illustrative potential difference between the electrodes l2 and the companion electrode member 13 is about 17 kilovolts effective, where the gap length is substantially 0.5", Preferably, the

voltage is sufficient for the discharge to bridge the gap while no flour is present. Preferably, a he common electrode member 13 is maintained at ground potential, being suitably grounded to the apparatus, while preferably all of the electrodes it are maintained at the high potential relative to the common electrode it, but preferably by way of certain safeguards later described.

The grounding of the rotating and common electrode member I3 to the grounded frame of the apparatus would, with the construction of Figure 3 as .thus far described, take place through the bearing members 54 and 59 by ably of cast nickel-iron formed on or secured to it in any suitable way, as. for example, by utilizing the central passageway 5| to receive a studlike extension of the member 93, and pinning or otherwise securing the two together; member 93 is disk-shaped and on its under face is'recessed so as to provide a peripheral retainer wall 93 which is concentric with the axis of the tubular support 59.

In the bottom end of the motor casing 88. as viewed in Figure 3,-there is provided a portion 94 also recessed to provide a peripheral wall 9 I which in course of assembly of the parts hecomes juxtaposed to the peripheral wall 93 of member 93. a relatively large metal ball 95 being interposed between the two and being preferably.

of slightly less diameter than the spac ng between the contiguous faces of the recessed mem bers 93 and 94. The ball 95 is held a ainst dropping out by the companion peripheral wall members 93 and 94* whose insidefaces are preferably inclined to form a suitable angle and to to both.

Accord ngly, as the motor rotates the ball 95 is pro elled centrifugallv into tan ential contact with the inclined faces of the wall members 93" and 94* where, in rolling contact it revolves about the motor axis at about half the R. P. M.

of the motor. Thus,- the ball acts as a ood contact-making bridge between the rotating parts and the stationary parts. assures dependable complet on of the high tension circuit to ground and at the same time relieves the bearings from conductin appreciable current.

Electrodes I2 are preferably arranged and constructed to be mounted or supported in groups, preferably in groups of as many electrodes as there are vertically displaced rows of electrodes, namely. three in the illustrative embodiment. In Fi ures 5, 6 and 7 is shown such a group mounting or assembly. It preferably comprises a support 98 of moldable solid dielectric material preferably of low dielectric loss factor. of the general confi urat on shown in these fi ures, to provide a hor zontal led e 98 just above an inclined ed e 98 from which project cylindrical portions 98. one for each electrode. and each havin an electrode 72 molded into it along its axis. The electrodes I2 may comprise a cylindrical wire-like member of a diameter ap-.

asiasos ably made of nickel, and projecting beyond the end faces of the cylindrical extensions 98 to an appropriate extent as indicated in Figure 6.

The wire-like material of the electrodes extends inwardly into the main body portion 98 of the member 98, the several wire-dike members I2 being appropriately bent or conformed, as is better shown in Figure 6, to extend upwardly along and within the main body part 98 in spaced relation so as to be insulated from each other, being thence extended substantially horizontally to be exposed respectively in cylindrical recesses 98' in the left-hand vertical edge 98 of the member 90, the exposed ends l2 being threaded as shown in Figure 6. These wire-like parts are molded as inserts within the member 98.

Referring now to Figure 3, the frusto-conicai insulating member or support 66 is provided with or has molded into it a series of holes arranged according to the desired distribution of the electrodes 12: thus, in the illustrative embodiment.

' the holes are alined in three vertically spaced cirpermit the ball 95 to be positioned tangentially cles, being in number seventy-two holes per circle,and they are also alinedvertically to form in effect vertical rows or groups corresponding to the grouping of the electrodes '12 in the supporting member 98 of Figures 5, 6 and 7. For each the support 68, the solid dielectric cylindrical ex-.

tensions 98 with the protruding electrodes I2 of each being entered into the holes ofa vertical row of holes in member 88, thus to bring the electrodes 12 into juxtaposition and alinement with the companion electrode I3, suitable washer-like sealing elements I00 (Figure 3) being slipped over the cylindrical extensions 98, thus also to form an effective seal in the event that there is any looseness or play in the fitting of the cylindrical extensions 98 in their respective holes.

Each electrode mounting member 98 is provided with a horizontally extended lug 98 at its upper end and with a downwardly extended lug 98 at its lower end (Figure 6) and as each member 98 is assembled to the frusto-conical dielectric support 86, as above-described, lugs 98 and 98 are brought into abutting relationship respectively with the inner cylindrical face or edge 38- of the ring member 38' and with the inner cylindrical face of an annular flange 65 formed in the flange 65; by these cylindrical edges or faces, all of the members 98 are neatly alined to form an annulus, as better appears in Figures 3 and 2, and thereby alsothe ends of the electrodes I2 become accurately alined witheach other and with the inner surface 14 of the electrode member I3 and non-uniformity of spark gap length avoided. 4

Into eachrecess 98 0f the members 98 is received a connector which preferably takes the, form of that shown in Figures 8 and 3 'at IN. I

comprises a metallic tube I02 covered with a threaded ends 12 of the wire member 12 exposed in the recess 98 of the member 98. The solid about the metal tube I 02 is at its right-hand end preferably of a diameter to fit snugly into the cylindrical recess 98 of the member 98.

The connector elements IOI may thus be easily assembled to the members 98 but this is preferably done after the latter have been set in place as above described and as is shown in Figures 2 and 3, the vertical rib of the angle-cross-sec tioned ring member 38 being provided with suitable apertures or being broken away at appropriate intervals as at 38? (Figure 3) to permit the connector members IM to be entered therethrough and into the recesses 98 of the members 98, the connector elements IOI thus projecting radially outwardly beyond the supporting ring 38 and toward the cylindrical wall portion 30 of the casing; this they do in vertically displaced layers, ilustratively three, as is better shown in Figure 3. The connector members IOI are also preferably of differing lengths in order to facilitate a more compact arrangement of other parts and of the electrical connections, about to be described, for effecting energization of the spark gaps. I

In this latter connection I prefer to effect energization of the spark gap circuits in such a way that I am enabled to prevent excessive flow of electrical energy and hence prevent the dissipation, with possible detrimental or destructive results, of excessive energy in the spark gaps or in any one of them. For example, an excessive or too heavy energy dissipation in a spark gap or in the spark gaps might carbonize or burn the flour.

Where, as-in the illustrative embod ment being described, I utilize a single source of high potential for energizing the electrode circuits, such as a step-up transformer, indicated generally in Figure 3 by the reference character I06, I prefer to provide each electrode circuit with suitable protective or energy-limiting means. Thus, the transformer I06 may be of any suitable construction and-is preferably positioned, as shown in'Figures 1 and 3, substantiallyunderneath the bottom wall portions 26-21 of the casing, and by this arrangement, with one side of its high voltage winding grounded and the other led to a suitable high voltage terminal insulator I 01 (Fig ure 3) of any suitable construction, the terminal insulator I0! may be made to enter the interior of the cas ng through the bottom portion thereof. at a suitable point preferably such as is indicated in Figures 3 and 9. The transformer I06 may be connected to any suitable source of relatively low voltage energy through terminals I08 (Figure 3).

From the high voltage terminal I01 the high voltage electrodes I2 are energized and the protective or energy-limiting means above-mentioned preferably comprises a capacitor, but in the manner used is better termed an elastor. Preferably, there is one elastor for each electrode circuit, conveniently taking the form of that shown in Figure 4 and generally indicated by the reference character I09. The device I09 comprises a sealed tube or envelope IIO of solid dielectric material, such as Pyrexf glass. and it contains a gaseous dielectric medium, illustratively neon, at a pressure of about 50 millimeters Its left end portion is exteriorly covered with a conductive coating III and a coating II2 extends over its right-hand external portion.

The coatings III, II2 may be applied in any suitable way, preferably by spraying a suitable metal onto the tube surfaces. Also, they are preferably arranged to permit electrical connec tion to be made thereto conveniently. Thus, metal covering III is provided with two cylindrical band portions III and III", spaced from each other as shown in Figure 4, while covering H2 is provided with a cylindrical band portion II 2 preferably of reduced diameter and hence preferably sprayed onto a restricted extension of the tube I I0. One such device I09 is provided for each electrode circuit and I arrange them concentrically with the central vertical axis of the apparatus and in the generally annular space between the cylindrical casing portion 30 and the upper portion of the member 28.

Members I09 I also preferably mount so as to be easily replaceable. And referring to Figures 3, 9 and 2, I provide a metal annulus I I5 having therein holes IIB corresponding to the number of devices I09 and equalling in number the number of electrodes I2; the holes II 6 are arranged in circular and radial groups (Figures 9 and 2). Thus, they may be arranged in six circular groups to permit staggering of the radial groups and hence to achieve better compactness of arrangement, while the radial groups are in number the same as the number of electrode supports 98. Where the latter have three electrodes and hence three connecting devices I III,

each radial row (Figures 9 and 2) has three holes" 6 and each radial row is alined under the radius of an electrode support 98,v as is better shown in Figure 2.

The thus apertured annular support I I5 is supported concentrically in the annular space within the casing portion 30 (Figure 3) in a position 1 tubes, the outer of which seats in the upper end of leg 25, being'thereby grounded thereto, and

the inner of which, grounded to leg 25 by conductor H9, receives the lower end of a cup-like member H9 in which is' seated the lower end of the support II 8.

The annular support II5 has suitable means for engaging the upper ends of the insulating I supports I I8 and they may comprise socket-like brackets I2I (Figure 3) suitably secured to the support I I5 and shaped to takeover the upper ends of the insulating supports II8.

The annular support H5 is connected' as by I a conductor I22 (Figures 3 and 9) to the high voltage side of the transformer I06 and hence to the connecting element of the insulating terminal I01, thus maintaining the suppo t I I5 at high potential. In each aperture H6 is secured a metallic tube-like member I2 3, closed at its lower end as shown in Figure 3, and of an internal diameter and of a length or depth appropriate to receive-the'left-hand end (Figure '4) portion Pf the elastor I09, thus bringing the band portions 'II I and III into snug engagement with lower and upper portions respectively of the internal cylindrical walls of the tube support I23, and also efiecting electrical connection therebetween. Preferably, a suitable cushioning material I24 such as metallic Wool, is placed in the bottom of each socket-like member I23 against which the lower end of the elastor E09 may rest,

Spaced upwardly from the annular support HI 5 is an annulus I26 of solid dielectric material, such as Bakelite, provided with holes I28 so distributed that they register respectively with the upper open ends the tube or socket members I23 (Figures 3 and 9) insulating member E26 is held spaced upwardly from the socket-holding annulus I I5 by any suitable means, such as studs or pillars I29 (Figure 3) made preferably of solid dielectric material and acting also to hold member I 26 against movement relative to the member II5 so as to maintain the openings in both in registry.

Also, as shown in Figure 3 the tube or socket members I23 are preferably of a depth sufiicient to accommodate so much of the elastors I09 as is commensurate with the extent of the outer metal covering III, the upper ends of the elastors I09, with their coverings II 0 extending upwardly to terminate in a plane somewhat below the space into which the connector elements IOI project, insulating annulus I26 being supported at such a height as to fall in a plane substantially midway of the two planes in which the adjacent ends of the coatings IIO, III of the elastors I09 respectively fall.

Thus, the reduced-diametered ends II2 (Figure 4) of the elastors I09 are all presented upwardly just underneath the insulated connectors IOI. By means of a springor resilient 'metal cap I (Figure 3) which can be snapped or forced onto the reduced end N2 of the elastor I09 and which has connected to it a bare wire I3I, the coating II2 of each elastor I09 is electrically connected to a connector IOI and this connection may be quickly and simply effected by simply inserting the free end of the wire I3I into the outer open end of the tube I02 (Figure 8) of the connector element IOI.

With the holes and tube or socket members arranged as above described (see Figures 2 and 9)' and with the elastors I09 set into place therein, the elastors become arranged in radial rows of three each, with each row alined with the vertical or radial plane of the connectors IOI projecting outwardly from each electrode support 98. With this arrangement the innermost elastor I09 of any one radial group is connected by a wire I3I to the lowermost connector IOI of the group carried by the electrode support 98, the intermediate elastor is connected to the intermediate connector IN and the outermost elastor connected to the .uppermost connector I0'I and for this purpose, and as shown in Figure 3, the connectors IOI are preferably of progressively varying lengths so as to terminate substantially immediately above the elastors to which they are respectively to be connected.

With the annular support I I5 and the tube or socket members I23 maintained at high potential, as above described, the metal coatings II I of the elastors I09 are likewise maintained at the same potential, relative to other parts of the apparatus. The gaseous content, illustratively neon, of the elastors I09, being subjected to a relatively high dielectric field-or stress, becomes conductive and iorms with the metal covering I I I the twoelements of a capacitor with the intervening wall of the glass tube or envelope H0 as the intervening dielectric. Withsthe illustrative numerical or dimensional values as above set forth, the capacitance of this capacitor is on the order of 250 micro-microfarads.

But at the other end of each elastor I09, a similar capacitor structure and action exist in that the conductive gaseous medium within the enve-= lope I I0 and the other outer covering E 62 form the conductive or electrode parts of another capacitor with the intervening wall of the envelope as its dielectric, and in capacitance it is preferably the same as the other capacitor.

But these two capacitors will be seen, by the construction, to be in series, and hence give an effective capacitance of half the value of each and hence a capacitance of 125 micro-microfarads.

Accordingly, the circuit of each electrode '82 has included in it such an elastor and thereby the current flow in each circuit is definitely limited to a safe value, a value which, if materially exceeded, might give rise, as earlier above pointed out, to dissipation of so great an amount of energy in the spark gap as might carbonize or burn the flour, or bring about undesirable effects.

Should the envelope IIO of an elastor I09 become punctured or otherwise break down, the ingress of air into the envelope at atmospheric pressure makes the device non-conductive and current flow through the circuit of the punctured elastor ceases.

, Should the puncture be minute and of such a character as to short-circuit or destroy the capacitor action of one of the two capacitors of each elastor I09, the capacitance of the remaining capacitor remains in the circuit and with the efl'ective capacitance in that particular circuit now approximately doubled, the energy flow in that circuit still cannot exceed about twice its original value, the factor of safety being selected to permit even such a doubling of the energy to take place but air at atmospheric pressure ultimately fills the envelope of the elastor even if the puncture is minute, and thatparticular circuit becomes inefiective since the elastor than becomes non-conductive.-

Should such a rupture of the envelope of an elastor I09 take place as would cause a shattering or breakage of it in such a way as to permit its upper part with the metal coating H2 or a part thereof to move downwardly, the insulating annulus I26 stops such downward movement and thus prevents a direct closure of the discharge I 09 are accommodated, as above described, is well within the annulus defined by the outer circumference of the frame ring 38 and the inner circumference of the flange 30 of the cylindrical side wall portion 30 of the casing, thus to permit the elastors I09 to be freely withdrawn or inserted from above. For this purpose, I provide, in the casing structure, suitable means'for achieving ready access and such means preferably takes the form of a hand hole I33 shaped as shown in Figure 2, being in general arcuate and of arcuate and radial extents sufficient to encompass within its area, when projected'downwardly, as seen in Figure 2. a convenient or suitable number of elastors. Hand hole I33 is provided with a cover plate I34 (Figure 1) having any suitable means, such as screws, for readily detaching it and thus exposing the hand hole I33.

As earlier described, the cover plate 3|, also annular in shape (see Figure 2) is preferably secured peripherally to the flange 30 (Figure 3) as by screws 44. Accordingly, when access to the interior is desired, for example, to replace an elastor, the screws 44 are removed, leaving the top plate-3I resting at its outer periphery on the flange 30 (Figure 3) and with its inner periphery in the rabbet 42 of the collar or ring 4 I. With the cover I34 of the hand hole I33 removed, the top plate 3| may now be swung about the central vertical axis of the apparatus to bring the hand hole I33 over that group of elastors in which is included the elastor to' be replaced.

Replacement through the hand hole is quick and easy; the connector elements IOI, after the connecting wires I3I are withdrawn therefrom, may be quickly unscrewed from the electrode supports 98, where necessary, thus to clear the path for upward withdrawal movement of the elastor in question and for insertion of a new one, whence restoration of the parts proceeds with the same facility.

In Figure 2 it will be noted that I prefer also to provide a hand hole I35 spaced inwardly of the hand hole I33 and also covered by a detachable cover plate I 34 (Figure 1). Hand hole I35 is of an expanse and location such that it falls over part of the annulus formed by the upper horizontal lugs 98 of the electrode supporting members 98 (Figures 6, 3 and 2), whereby ready access to the latter for replacement may be achieved, as is better seen in Figures 2 and 3.

Accordingly, through the hand hole I 35 with the cover plate I34 removed, access to any of the members 98 may be readily gained, as, for example, for purposes of replacement, the electrical connections and connectors being removed through the hand hole I33. To facilitate handling of the members 98 through the hand hole I35, I prefer to provide each with 2. lug 98 (see Figures 6, 7 and 3) aperturedas at 98*.

With all of the members 98 fitted in position as above described and as shown in Figures 2 and 3, the lugs 08 are alined about the inner face of the annulus which the members 98 make up in'the aggregate, with the holes 98 exposed upwardly in these lugs. Accordingly, a rod, or the like, may be used and extended through the hand hole I35 and with its end passed into or through the hole 98 of the lug of a member 98, the latter may be manipulated to release it from its interfitted position or relation with respect to the coacting supporting and alining parts.

More specifically, the member 98 (see Figure 3) may in this manner be more easily given a movement inwardly toward the.central axis of the apparatus. thus to withdraw the cylindrical portions 98 thereof from the holes in the insulating support 66, whence the member may be withdrawn upwardly through the hand hole I35. For example. the abovementioned rod may be passed completely through the hole-in the lug to bring its lower end to bear against the wall of annular groove I40 which may thus act as a fulcrum for the rod and whereby the member 98 may be moved inwardly to withdraw its parts from the member 66.

Thus, servicing or maintenance of the apparatus may be easily and conveniently maintained.

In this connection, it might also be noted that the moving parts are few in number and are simple and that, with their rugged mounting, they are well adapted for long continued operation.

About the periphery of collar 63 are provided air impeller blades 63 (Figure 3) efiective to impel air downwardly through the annular passageway between the uppermost externalcylindrical surface of sleeve shaft BI and the vertical wall of counterbored portion 49 of hub 49, thus to prevent ingress of flour to the bearings and other parts internally of the sleeve shaft 6|. A passage or channel I 38 provided in the parts 48 and 4| and connected to an external conduit I39 supplies air to the impeller blades 63- for the above purpose.

In Figures 11-20, I have shown an appara us and arrangement for otherwise achieving energization of the electrodes and for limiting the energy of discharge to a safe value. In this form of apparatus -I provide a disk-like base' plate or casing bottom I4I (Figure 11) preferably supported at a suitable height above the floor as by standards'or legs I42 which, like the legs 25 of Figure 3, may be four in number and equiangularly displaced about the central vertical axis of the apparatus. The bottom frame I4I has at its center and along the vertical axis of the apparatus an exit opening I43 to which, like the opening 33 of Figure 3, connection may be made as by a pipe or conduit to pass the treated product away from the apparatus. Surrounding this opening and preferably integrally formed with the bottom frame MI is an upwardly extending sleeve I44 which at its upper end is received into the lower end or opening 33 of the member 28, being secured thereto by suitable screws I45, as shown in Figure 11.

The member 28 coacts with parts similar to those described in connection with Figures 1*!) and these parts are hence designated by the same reference characters, their functioning and coactions being now clear from what is set forth above in connection with Figures 1-9.

The lower outer face of the frame sleeve I44 (Figure 11) is shouldered as at I46 to' receive the inner race of an anti-friction bearing I48, and slipped onto member I 44 and abutting against this inner race is a spacer sleeve I49 against the upper end of which rests the inner race of an anti-friction bearing I50. The parts are so diametered that the lowermost end of the member 28 slips over the upper end of the frame sleeve I44 to rest against the inner race of bearing I50, the weight of the parts, supplemented by the securing action of the screws I45, thus insuring maintenance of dependable assembly of bined radial and thrust bearings and the outer races thereof support, for rotation about the central vertical axis of the apparatus, a cylindrical part I5I which I shall hereinafterfor convenience term a rotary frame and which, as is later described, carries and moves the moving parts of electric generator means that coact in a peculiar and unique way with the electrodes of the apparatus. This rotary frame I5I may be driven in any suitable manner but preferably in the manner about to be described, certain features of the mounting of member I5I being preferably made to take part in this preferred form of drive. I

Thus, I provide a sleeve I52 diametered to be received over the outer races of bearings I48 and I50 with a spacer sleeve I53 (Figure 11) between the later, sleeve I52 being shouldered. as at I54 to transmit any downward thrust to the inner race of bearing l50 and through the spacer sleeve M9 to the inner race of bearing I48.

Near its lower end the sleeve I52 has a shoulder I55 against; which thelaminations of a rotor I56, with its clamping plates, rests, being clamped against the shoulder I55 by a sleeve-like hub I58 of the rotary frame I5I to which the hub I58 is connected by integrally formed radially extending ribs I59. The ribs I59 are of suitable number, illustratively four as shown in Figure 12, and the latter preferably have surfaces I60 (Figure 12) of suitable expanse, curvature and inclination, to function, when rotating in clockwise direction, as viewed in Figure 12, as a fan or air impeller to move air upwardly, as viewed in Figure 11, and for a purpose later described.

The sleeve-like hub I58 fits over the sleeve member I52 and at its lower end engages the upper face of the rotor structure I56; at its upper end it has an internal shoulder or flange I6I which takes against the upper end of the sleeve I52 to which it is secured as by screws I62. The rotary frame I5I may thus freely rotate about the central vertical axis of the apparatus, as does also, by the same mounting, the rotor I 56.

A suitable stator or field structure comprising an iron core or laminations I63 and energizing windings I64 '(Figure 11) extends about the rotor I56, being supported by an upstanding annular flange I65 preferably formed integrally with the bottom frame MI and provided with an'internal shoulder I66 against which the core structure I63 rests and against which it is clamped by a clamping ring I68 (Figures 11 and 12) which is secured to the flange I65 as by screws I69.

The stator or field windings I64 are energized from any suitable source of electrical energy, preferably alternating, connection being made by way of conductors I10 (Figure 11) carried to the exterior of the apparatus by means preferably of a suitable conduit or pipe I1I which, as shown in Figure 11, may be threaded into the stator-supporting ring or flange suitably energized, therefore, the rotor I56 is set into rotation and with it the rotary frame I5I.

The rotation of the rotary frame I5I I utilize in coaction with other-parts to effect the generation of electrical energy in suitable form for energizing the discharge electrode circuits and I preferably utilize and provide a separate generator for each electrode circuit and preferably a generator having the characteristic of being incapable, under given conditions of operation,

of supplying energy beyond a certain magnitude or value. Accordingly, in this illustrative form, where I employ three circular rows of electrodes 12 with '72 electrodes in each row, thus totalling 2'16 electrodes and electrode circuits, I provide 216 generators, one for each electrode circuit. These generators are preferably of a very simple and inexpensive form and construction and the moving parts thereof I mount on the rotary frame I5I; for convenience in assembly and compactness of arrangement, I may arrange these generators in any suitable number of circular I65. When I rows or series, one above the other, and illustraaeiases prefer to mount on the rotary frame I5I is the field-producing element and preferably takes the form of a permanent magnet and hence comprising a suitable metal or alloy appropriately treated and permanently magnetized. It may, therefore, be given a simple and inexpensive conformation or shape, such as a plain bar of rectangular shape and cross-section, as shown at I13 in Figures 11 and 12. The rotary frame I5I I preferably provide in its outer cylindrical face with vertically extending T-slots I14 (Figures 11 and 12) and where 36 generating units are to be arranged in one circular series, these T-slots I14 are 36 in number and in length they are sufiicient to accommodate in each as many permanent magnet field bars as there are to be series of generating units, illustratively six. Thus, in Figure 11, six magnet bars I13 are shown accommodated in each of the two T-slots that appear in that cross-section, the lower ends of the T- slots being closed in any suitable manner as by a ring I15 suitably secured as by pins I16 to the lower end of the rotary frame I5I. Adjacent ends of the magnet bars and their pole pieces are preferably separated by a suitable thickness of a yieldable'non-metallic means, such as paper, as at IBI, and of configuration to fit T-slot I14, to provide ample leeway for relative differences between the temperature coefiicients of expansion of the materials of the field construction and of the material of the rotary frame I5I, the latter being illustratively made of aluminum.

As better appears from Figure 12, the magnet bars I 13 preferably do not completely fill the base portion of their respective T-slots I14, thus leaving a T-shaped space for the reception of certain T-shaped parts.

The latter comprise pole-pieces I19 and spacers I and I8I (Figure 11); the pole-pieces I19 are preferably laminated and shaped as shown in Figure 16, being provided with any suitable form of amortisseur winding, as indicated by damper bars I82 and plates I82 to damp out the effects of the pulsating armature reaction. The spacer member I80, lik the pole-pieces I19, is also T-shaped and similarly dimensioned as to crosssection to fit snugly into so much of the T-slots I14 as is not occupied by the magnet bars I13, and in Figure 17 spacer I80 is shown in perspective. Spacer I80, moreover, is made of a suitable non-magnetic material and preferably of a solid dielectric like moldable Bakelite.

In assembly, therefore, and viewing Figure 11, the pole-pieces I19, the long spacers I80 are inserted into those outward portions of the T-slots I14 not occupied by the magnet bars I13 in appropriate sequence, as shown in Figure 11, sothat two pole- -pieces I19 become positioned adjacent the respective ends of each permanent magnet field piece I13, the long spacer I80 determining the spacing therebetween, and so that a short spacer IBI becomes interposed between the twopole-pieces and the adjacent ends of two successive magnet bars. Preferably, the parts are relatively tightly fitted into the slots so as to insure rigidity and immovability of mounting or assembly, and the upper open ends of the slots I14 are closed in any suitable manner as, for example, by a ring I83, companion to the ring I15, and secured in any suitable manner to the upper end of the rotary frame I 5|, as by pins I84 (Figme 11) Thus, there are provided six ring-like series of generator field structures, each comprising a permanently magnetized field piece with two pole-pieces, the resultant pairs of pole-pieces I 9 being in each Series equidistantly or equi-angularly spaced about the periphery of the rotary frame member II. The pole-pieces may project slightly from the peripheral or cylindrical face of member I5I while the outer faces of the spacers I and I8I are preferably flush with the outer cylindrical face of member I5I..

For each field structure, which will thus be seen to be substantially U-shaped (see Figure 11) I provide a mating or companion U-shaped core of magnetic material, preferably laminated, with a'winding for each, and to simplify manufacture and assembly I preferably employ a construction as follows: 7

Thus, referring first to Figure 11, there is there shown such a. winding, as above mentioned, at I85, which may be form wound to be received on, or may be directly wound upon, a winding support I86, better shown in Figure 14 as comprising a cylindrical sleeve I81 for directly receiving the winding and an end disk I88, provided with .a hole I89 through which one end of the winding I may be drawn for subsequent electrical connection; the sleeve I81 has an axially extending aperture I of cruciform shape matching the cross-section of a core member later described.

Companion to the w nding support I86 is a housing member generally indicated at I9I and better shown in Figure 13; like the support I86, it is preferably made of solid dielectric material of low dielectric loss factor like moldable polymerized styrene. It comprises a cylindrical easing portion I92 closed at one end by a disk-like end wall I93 having at its center a cruciform aperture I 94. In its cylinder wall it has mounted an electrical connecting device I (Figures 11, 12 and 13), comprising a tubular stud with external lock nut and an external spherical member screw threaded to fit the stud portion and to receive conductor 2I8 as shown in Figures 11 and 13.

As the windingon its support I86 is inserted into housing part I 9| the wire of the high voltage end of winding is pulled through the tubular stud. When winding is finally positioned in housing I9 I, by means of rabbet I96 which forms a seat for the disk part I88 of support I86, the wire issoldered to external end of the stud and the excess wire cut off. The spherical member of I95 is then screwed on the stud member.

Housing member I9I has a radial extension I98 preferably of the same axial length as that of the cylindrical housing part I92, being hollowed out,

} if desired, as at I99. On its two parallel axially extending races. the extension I98 is provided with grooves 200 that extend parallel to each other and parallel to the'axis of the winding housing and of the cruciform registering core apertures I90-I94.

Where several vertically displaced series of generator units are to be prov ded, I may and preferably do arrange the stationary elements thereof in vertical rows, just as the permanent field magnet. bars I13 (Figure 11) with their respective pole-pieces are arranged in vertical rows. and where six vertically displaced series of'unifs are. to be provided, each of these rows contains six elements; accordingly, as shown in Figure 11 each vertical row of stationary elements comprises six windings I85 each with its housing-like support I86-I9I, arranged with their cruciform apertures I90 in alinement to facilitate reception of, and axial alinement by, a core piece 20I which, being preferably laminated and preferably cruci-' form in cross-section, thus snugly receives the cruciform apertures ISO-I94 of these winding housings.

But also strung onto the core piece 20I and in suitable order or sequence with the winding housing units are core pieces 202, being shaped substantially as shown in Figure 15 and hence having an aperture 204 of cruciform shape at one end and opposed recesses or grooves 205 dimensioned and spaced to match the grooves 200-200 of the part I9I of Figure 13. The pole-pieces 202 are preferably laminated and hence comprise a suitable number of pieces of dynamo steel, or the like, each shaped as is shown in Figure 15.

The axial length or dimension of the winding housing unit I86-I9I is the same as the length of the spacer members I80 (Figure 11) that determine the spacings between the pole-pieces I19 of the permanent magnet bars H3. The core pieces 202 match in thickness two pole-pieces II9 and a spacer I8I. I

Accordingly, when these parts are strung onto the long cruciform cross-sectioned core piece 20I in the sequence shown in Figure 11, they become alined to each other so that the opposed grooves 200-200 of the housing parts I86-I9I and the opposed grooves 205-205 of the pole-pieces 202 become respectively alined with each other and form two continuous opposed grooves, the inter- 30 fitting of the core piece 29I with the apertures of these several members bringing these parts into proper alinement to register these grooves. That end of each winding I 85, that is brought out through the hole I89 (see Figure 14) in the end disk I88 is, in course of this assembly, grounded to the apparatus in any suitable way as, for example, to the core pieces 202, as indicated at 201 in Figure 11. Suitable means, such as end collars 206, fitted onto the respective ends of the core piece 20I and secured thereto in any suitable way, hold all of these parts assembled to form a single sub-assembly having, for each winding I 85, an individual U-shaped core structure, each comprising a portion of the core piece 20I and two core pieces 202, the ends of the latter being spaced to match the spacing of the pole-pieces I19 of thefield magnet I13. I

In the illustrative example, 36 such sub-assemblies are built up and then grouped concentrically about the cylindrical frame member I5I for coaction with the field core structures carried by the latter, these sub-assemblies being preferably uniformly spaced from each other in any suitable way. Preferably, I utilize the registering opposed grooves 200-205 to take part in this action and thus I may provide vertically extending members 200 each provided with tongues209 (see Figure 12) in its opposed edge faces for interfitting engagement with the alined grooves 200-205 of the sub-assemblies. The sub-assemblies and these tongued members 208,'when thus alternated with each other, bring about such aline-. -ment of the faces of the core members 202 as to make the latter coincide with a cylindrical surface whose rad us is but slightly greater than the cylindrical surface in which the faces of the polepieces I79 on the rotary frame I5I terminate. Ihc difference in these two radii being the desired magnitude of the air gap between the stationary and moving parts of the magnetic circuit of any generator unit of all of the series.

The members 208 are formed, by slotting, from the integral coaxial cylindrical part 2 I0 of frustoconical member 28. This cylindrical part 2I0 depends from annular flange 2| 6 of casting 28,

and terminates in a. flanged portion 2W. This fiange2l0 is positioned on casing bottom ME by rabbet 2I2 formed thereon and is fastened by screws 2i i.

As the bottom of each slot formed between members 208 is semicircular, due to the action of the slot cutting tool, semicircular inserts 208 are therefore provided to form horizontal bases for the lowermost of the core legs 202, as indicated in Figure 11.

Non-magnetic grooved spacer members 2I3 are provided one for each slot. Each of these members, when assembled, extends upwards slightly above the upper surface of annular flange 2I5, and is forced downwardly by screw 2I5 and clamping plate 2 I 4 atop of each member 203, thus holding a series of core legs 202, radial extensions I98 of coil housings I9I, and insert 200 in compression. Holes 2H5 in member 2I6, and holes 2 III in lower part of member 2 I just above flanged portion 2I0 are provided for air circulation..

With the assembly thus far completed, there are accordingly presented, alined along an imaginary cylindrical surface, all of the terminal connectors I95 (Figures 11, 12 and 18) of the windings I85, being arranged in '36 equi-angularly spaced rows, and by means of conductors 2 l9 connected to the devices I95, the windings 1185 are connected respectively to the connectors WI and hence to the electrodes 12. 7

As appears from Figures 11, 12 and 18, the conductors 2 I8, which may be bare wires of appropriate rigidity and of 'suflicient diameter to prevent corona, are suitably bent to maintain appropriate spacings between each other as they extend upwardly from the connecting devices I95 to the connectors IOI. For example, the three conductors from the upper three terminals I95 extend to the three connectors IOI, respectively, of one electrode support 98, while the three conductors from the lower three terminal devices I95 extend to the three connectors IOI of the next adjacent electrode support 98, the circumferential spacings between the vertical rows of devices I95, as better appears in Figures. 12 and 18, giving adequate space for accommodating these conductors 2I0 while maintaining adequate spacings therebetween. Thus, each vertical row of generator elements is electrically connected to the connectors of adjacent electrode supports.

With the common electrode and conveyor element 13 (Figure 11) rotating as was described earlier in connection with Figures 1-9, the movement of the flour takes place as was earlier described; with the rotary frame II rotating at a suitable speed by energization of the windings I5 3, the generator units are also inoperation and in the illustrative embodiment each generator armature is in the circuit of one electrode 12. During the rotation of the rotary frame 959, all of the field-producing magnet bars I13 in any one circular row or series are, during a single revolution, presented successively into coacting relationship with the core pieces of all of the stationary elements of that series; For any one winding I55 and its U-shaped core structure (202-201-202), the magnetic field is, built up' and collapsed once for each time that a permanent magnet bar I13 with its pole-pieces I19 is brought into and out of juxtaposition to the core pieces 202-202; for one revolution that happens 36 times and, the speed of drive of the member I5I is therefore selected, in relation, of course, to other factors, to give the desired freaeiaeca quency of alternating E. M. F. generated in the windings I85. An illustrative rate of drive is about 420 R. P. M., hence seven revolutions per second and, with 36 elements in a series, as above assumed, the frequency generated in each winding I is accordingly 126 cycles per second, if the magnet permanent bars I13 in the series are, as to their polarity, alternated or reversed end for end throughout, in the manner indicated in Figure 20 where two successive generator units of each of two circular series are shown schematically and where the alternated polar relationships of successive permanent field pieces I13 is also indicated. If these permanently magnetized field pieces I13 are, in any one series, not thus alternated as to polarity but are arranged as is indicated in Figure 19, the frequency of out put of any one winding I85 is double that achieved with the arrangement of Figure 20 and in the illustrative embodiment would be about 252 cycles per second. From the comparative arrangements shown in Figures 19 and 20, the manner of inserting the permanent magnet bars I13 in the vertical slots of the rotary frame I5I becomes readily apparent, according to whichever arrangement is adopted.

The magnetization of the permanent magnet bars I 13, the cross-sectional dimensions of the various pole-pieces'and core parts, and the number of turns in the winding I85 are, with relation to the above-mentioned factors, such as speed of drive, selected so that the output voltage of any one winding or generator armature is, in the illustrative example, about 17 kilovolts, that be-- ing the voltage illustratively set forth in connection with the specific dimensional embodiment described in connection with Figures 1 and 9. With that voltage effective upon each electrode 12, the preferred manner of functioning of the apparatus, in so far as concerns movement of the flour and destruction of insect life therein by the electrical discharge from the band-like array of electrodes 12, is substantially as was described in detail in connection with Figures 1-9. But over-energization of any one spark gap in the treatment zone cannot take place due to the fact that the individual generator units have the. inherent characteristic that their energy outputs are definitely limited.

The output of one of these generator units is sufficiently small and is inherently limited due to its small size and high internal impedance. The magnetic flux through the armature is limited to that of the permanent magnet I13 less the flux leakage of the magnetic circuit. Illustratively, the current may be arbitrarily limited to a value not exceeding one milliampere, and

tllek voltage as previously mentioned is about Thus, it is impossible to give rise to such an arc-over or discharge as would damage the flour or cause a dangerous or explosive condition.

The base frame MI (Figure 11) is upwardly flanged at its periphery and. suitably rabbetted as at 2I9 to interengage with a cylindrical casing structure generally indicated at 220, being detachably secured as by screws 22E. The casing structure 220 is preferably constructed to permit of ready access to the apparatus or parts thereof andfor this purpose I preferably construct it in sections.

Thus, it may comprise two half-cylindrical side wall portions 222223 (Figures 11, 12 and 18), respectively surmounted by half-circular top portions 225 and 225 (Figures 11 and 18) respec- 

